Muscle-Derived Mitochondrial Transplantation Reduces Inflammation, Enhances Bacterial Clearance, and Improves Survival in Sepsis.

BACKGROUND: Mitochondrial transplantation is a promising strategy for the treatment of several diseases. However, the effects of mitochondrial transplantation on the outcome of polymicrobial sepsis remain unclear. METHODS: The distribution of transplanted mitochondria in cecal ligation and puncture (CLP)-operated mice was detected at 2 and 12 h after intravenous injection in the tail (n = 3). Then, the effects of mitochondrial transplantation on bacterial clearance (n = 7), systemic inflammation (n = 10), organ injury (n = 8), and mortality (n = 19) during CLP-induced sepsis were explored. Microarray analysis (n = 3) was used to testify the molecular changes associated with decreased systemic inflammation and multiorgan dysfunction in sepsis. RESULTS: The extraneous mitochondria were distributed in the lung, liver, kidney, and brain of CLP-operated mice at 2 and 12 h after intravenous injection in the tail. Mitochondrial transplantation increased the survival rate of septic mice, which was associated with decreased bacterial burden, systemic inflammation, and organ injury. Spleen samples were utilized for microarray analysis. Pathway analysis revealed that in polymicrobial sepsis, gene expression was significantly changed in processes related to inflammatory response, complement and coagulation cascades, and rejection reaction. CONCLUSIONS: These data displayed that mitochondrial replenishment reduces systemic inflammation and organ injury, enhances bacterial clearance, and improves the survival rate in sepsis. Thus, extraneous mitochondrial replenishment may be an effective adjunctive treatment to reduce sepsis-related mortality.

Autologous mitochondrial transplantation for cardiogenic shock in pediatric patients following ischemia-reperfusion injury.

OBJECTIVES: To report outcomes in a pilot study of autologous mitochondrial transplantation (MT) in pediatric patients requiring postcardiotomy extracorporeal membrane oxygenation (ECMO) for severe refractory cardiogenic shock after ischemia-reperfusion injury (IRI). METHODS: A single-center retrospective study of patients requiring ECMO for postcardiotomy cardiogenic shock following IRI between May 2002 and December 2018 was performed. Postcardiotomy IRI was defined as coronary artery compromise followed by successful revascularization. Patients undergoing revascularization and subsequent MT were compared with those undergoing revascularization alone (Control). RESULTS: Twenty-four patients were included (MT, n = 10; Control, n = 14). Markers of systemic inflammatory response and organ function measured 1 day before and 7 days following revascularization did not differ between groups. Successful separation from ECMO-defined as freedom from ECMO reinstitution within 1 week after initial separation-was possible for 8 patients in the MT group (80%) and 4 in the Control group (29%) (P = .02). Median circumferential strain immediately following IRI but before therapy was not significantly different between groups. Immediately following separation from ECMO, ventricular strain was significantly better in the MT group (-23.0%; range, -20.0% to -28.8%) compared with the Control group (-16.8%; range, -13.0% to -18.4%) (P = .03). Median time to functional recovery after revascularization was significantly shorter in the MT group (2 days vs 9 days; P = .02). Cardiovascular events were lower in the MT group (20% vs 79%; P < .01). Cox regression analysis showed higher composite estimated risk of cardiovascular events in the Control group (hazard ratio, 4.6; 95% confidence interval, 1.0 to 20.9; P = .04) CONCLUSIONS: In this pilot study, MT was associated with successful separation from ECMO and enhanced ventricular strain in patients requiring postcardiotomy ECMO for severe refractory cardiogenic shock after IRI.

Bioenergetics Consequences of Mitochondrial Transplantation in Cardiomyocytes.

Background Mitochondrial transplantation has been recently explored for treatment of very ill cardiac patients. However, little is known about the intracellular consequences of mitochondrial transplantation. This study aims to assess the bioenergetics consequences of mitochondrial transplantation into normal cardiomyocytes in the short and long term. Methods and Results We first established the feasibility of autologous, non-autologous, and interspecies mitochondrial transplantation. Then we quantitated the bioenergetics consequences of non-autologous mitochondrial transplantation into cardiomyocytes up to 28 days using a Seahorse Extracellular Flux Analyzer. Compared with the control, we observed a statistically significant improvement in basal respiration and ATP production 2-day post-transplantation, accompanied by an increase in maximal respiration and spare respiratory capacity, although not statistically significantly. However, these initial improvements were short-lived and the bioenergetics advantages return to the baseline level in subsequent time points. Conclusions This study, for the first time, shows that transplantation of non-autologous mitochondria from healthy skeletal muscle cells into normal cardiomyocytes leads to short-term improvement of bioenergetics indicating "supercharged" state. However, over time these improved effects disappear, which suggests transplantation of mitochondria may have a potential application in settings where there is an acute stress.

Preischemic autologous mitochondrial transplantation by intracoronary injection for myocardial protection.

OBJECTIVE: To investigate preischemic intracoronary autologous mitochondrial transplantation (MT) as a therapeutic strategy for prophylactic myocardial protection in a porcine model of regional ischemia-reperfusion injury (IRI). METHODS: The left coronary artery was cannulated in Yorkshire pigs (n = 26). Mitochondria (1 × 109) or buffer (vehicle [Veh]) were delivered as a single bolus (MTS) or serially (10 injections over 60 minutes; MTSS). At 15 minutes after injection, the heart was subjected to temporary regional ischemia (RI) by snaring the left anterior descending artery. After 30 minutes of RI, the snare was released, and the heart was reperfused for 120 minutes. RESULTS: Coronary blood flow (CBF) and myocardial function were increased temporarily during the pre-RI period. Following 30 minutes of RI, MTS and MTSS hearts had significantly increased CBF that persisted throughout reperfusion (Veh vs MTS and MTSS; P = .04). MTS and MTSS showed a significantly enhanced ejection fraction (Veh vs MTS, P < .001; Veh vs MTSS, P = .04) and developed pressure (Veh vs MTS, P < .001; Veh vs MTSS, P = .03). Regional function, assessed through segmental shortening (Veh vs MTS, P = .03; Veh vs MTSS, P < .001), fractional shortening (Veh vs MTS, P < .001; Veh vs MTSS, P = .04), and strain analysis (Veh vs MTS, P = .002; Veh vs MTSS, P = .003), was also significantly improved. Although there was no difference in the area at risk between treatment groups, infarct size was significantly reduced in both MT groups (Veh vs MTS and MTSS, P < .001). CONCLUSIONS: Preischemic MT by single or serial intracoronary injections provides prophylactic myocardial protection from IRI, significantly decreasing infarct size and enhancing global and regional function.

Delayed Transplantation of Autologous Mitochondria for Cardioprotection in a Porcine Model.

BACKGROUND: We have previously demonstrated the efficacy of mitochondrial transplantation (MT) for the treatment of ischemia-reperfusion injury (IRI). We now investigate the efficacy of delayed MT by intracoronary administration in a model of regional IRI as a strategy for cardioprotection. METHODS: Female Yorkshire pigs (40-50 kg; n = 16) underwent 30 minutes of ischemia by snaring of the left anterior descending artery, and the hearts were then reperfused for 120 minutes. At that point, vehicle only or autologous mitochondria (1 × 109 in 5 mL of vehicle) were delivered as a bolus to the left coronary ostium, followed by a further 120-minute reperfusion. RESULTS: Echocardiographic analysis demonstrated that hearts receiving delayed MT after regional IRI had enhanced ejection fraction (P = .019), fractional shortening (P = .022), and fractional area change (P = .011) at 240 minutes of reperfusion compared with the untreated pigs. At the end of reperfusion there was a difference between the groups in measures of global left ventricular (LV) function such as LV end-diastolic pressure (P = .015) and rate of rise of LV pressure (P = .021). No significant differences were found between the groups in the area at risk (P = .48). Infarct size (% area at risk) was significantly decreased in hearts receiving MT compared with hearts receiving vehicle only (P < .001). CONCLUSIONS: Delayed MT by intracoronary injection appreciably decreases myocardial infarct size, increasing regional and global myocardial function. These results suggest that this can be a viable treatment modality in IRI, thus reducing long-term morbidity and mortality in cardiac surgical patients.

Myocardial rescue with autologous mitochondrial transplantation in a porcine model of ischemia/reperfusion.

OBJECTIVE: To demonstrate the clinical efficacy of autologous mitochondrial transplantation in preparation for translation to human application using an in vivo swine model. METHODS: A left mini-thoracotomy was performed on Yorkshire pigs. The pectoralis major was dissected, and skeletal muscle tissue was removed and used for the isolation of autologous mitochondria. The heart was subjected to regional ischemia (RI) by temporarily snaring the circumflex artery. After 24 minutes of RI, hearts received 8 × 0.1 mL injections of vehicle (vehicle-only group; n = 6) or vehicle containing mitochondria (mitochondria group; n = 6) into the area at risk (AAR), and the snare was released. The thoracotomy was closed, and the pigs were allowed to recover for 4 weeks. RESULTS: Levels of creatine kinase-MB isoenzyme and cardiac troponin I were significantly increased (P = .006) in the vehicle-only group compared with the mitochondria group. Immune, inflammatory, and cytokine activation markers showed no significant difference between groups. There was no significant between-group difference in the AAR (P = .48), but infarct size was significantly greater in the vehicle group (P = .004). Echocardiography showed no significant differences in global function. Histochemistry and transmission electron microscopy revealed damaged heart tissue in the vehicle group that was not apparent in the mitochondria group. T2-weighted magnetic resonance imaging and histology demonstrated that the injected mitochondria were present for 4 weeks. CONCLUSIONS: Autologous mitochondrial transplantation provides a novel technique to significantly enhance myocardial cell viability following ischemia and reperfusion in the clinically relevant swine model.